Selective and stable base pairing by alkynylated nucleosides featuring a spatially-separated recognition interface.

Unnatural base pairs (UBPs) which exhibit a selectivity against pairing with canonical nucleobases provide a powerful tool for the development of nucleic acid-based technologies. As an alternative strategy to the conventional UBP designs, which involve utility of different recognition modes at the Watson-Crick interface, we now report that the exclusive base pairing can be achieved through the spatial separation of recognition units. The design concept was demonstrated with the alkynylated purine (NPu, OPu) and pyridazine (NPz, OPz) nucleosides endowed with nucleobase-like 2-aminopyrimidine or 2-pyridone ('pseudo-nucleobases') on their major groove side. These alkynylated purines and pyridazines exhibited exclusive and stable pairing properties by the formation of complementary hydrogen bonds between the pseudo-nucleobases in the DNA major groove as revealed by comprehensive Tm measurements, 2D-NMR analyses, and MD simulations. Moreover, the alkynylated purine-pyridazine pairs enabled dramatic stabilization of the DNA duplex upon consecutive incorporation while maintaining a high sequence-specificity. The present study showcases the separation of the recognition interface as a promising strategy for developing new types of UBPs.

Alteration of target cleavage patterns and off-target reduction of antisense oligonucleotides incorporating 2-N-carbamoyl- or (2-pyridyl)guanine.

Antisense oligonucleotides (ASOs) are therapeutic modalities that are successfully used as pharmaceuticals. However, there remains a concern that treatment with ASOs may cleave mismatched RNAs other than the target gene, leading to numerous alterations in gene expression. Therefore, improving the selectivity of ASOs is of paramount importance. Our group has focused on the fact that guanine forms stable mismatched base pairs and has developed guanine derivatives with modifications at the 2-amino group, which potentially change the mismatch recognition ability of guanine and the interaction between ASO and RNase H. In this study, we evaluated the properties of ASOs containing two guanine derivatives, 2-N-carbamoyl-guanine and 2-N-(2-pyridyl)guanine. We conducted ultraviolet (UV) melting experiments, RNase H cleavage assays, in vitro knockdown assays, and off-target transcriptome analyses using DNA microarrays. Our results indicate that the target cleavage pattern of RNase H was altered by the modification with guanine. Furthermore, global transcript alteration was suppressed in ASO incorporating 2-N-(2-pyridyl)guanine, despite a decrease in the thermal mismatch discrimination ability. These findings suggest that chemical modifications of the guanine 2-amino group have the potential to suppress hybridization-dependent off-target effects and improve ASO selectivity.

Oligodeoxynucleotides Modified with 2'-O-(Cysteinylaminobutyl)carbamoylethylribothymidine Residues for Native Chemical Ligation with Peptide at Internal Positions.

We used native chemical ligation (NCL) to synthesize a 2'-O-{N-[N-(S-tert-butylthiocysteinyl)aminobutyl]carbamoylethyl} (CysBCE) ribothymidine-derived oligonucleotide to expand the variety of peptide conjugation sites, allowing the incorporation of peptides at the 2'-hydroxy group when the oligonucleotide forms a duplex with the complementary strand. The NCL reaction with a peptide thioester and the modified oligonucleotide proceeded smoothly even when the CysBCE modification was in the middle of the oligonucleotide sequence. In addition, we incorporated two CysBCEs into an oligonucleotide to conjugate two peptides to one oligonucleotide. The results indicated that the tandem NCL reactions proceeded efficiently when the oligonucleotide hybridized to the complementary strand to avoid intramolecular disulfide formation between the two CysBCE groups. This method could be useful for peptide conjugation on the 2'-position.

Insertion of a methylene group into the backbone of an antisense oligonucleotide reveals the importance of deoxyribose recognition by RNase H.

RNase H acts as a key effector in gene knockdown by antisense oligonucleotides (ASOs). Although various chemical modifications have been developed to regulate RNase H-mediated cleavage, precise control is yet to be achieved. In this study, we tried to address the question of whether the interaction of phosphate groups or deoxyriboses is more important in the recognition of DNA/RNA duplex by RNase H. To answer this question, we investigated the effect of methylene group insertion at the 5'-upstream or 3'-downstream phosphorothioate groups on RNase H-mediated cleavage. By inserting a methylene group at the 5'-upside or 3'-downside, the distance between phosphates or deoxyriboses could be changed in a different pattern. Maximum suppression of the cleavage reaction was observed when a methylene group was inserted at the 5'-phosphate group of the nucleoside which is known to distinguish ribose and deoxyribose via stacking of the W221 residue in RNase H. This effect was observed in a different sequence as well as mismatched duplexes, suggesting the interaction of deoxyribose rings with RNase H is more important than that of phosphate groups. Our results will contribute to the designing of further molecular modifications that improve the selectivity of RNase H-mediated cleavage reactions which allows for the development of allele-specific ASOs.

Synthesis of 2'-O-[3-(N-methylsulfamoyl)propan-1-yl]ribothymidine as a potentially applicable 2'-modified nucleoside for antisense oligonucleotides.

A synthetic scheme was developed to derive a modified ribothymidine bearing a 3-(N-methylsulfamoyl)propyl group on 2'-oxygen (TMSP). For synthesis initiation, a nucleophilic attack of 1,2-ethanediol on 5'-protected 2,2'-anhydro-ribothymidine was performed to selectively modify the 2'-position. After protection of the 3'-hydroxy group, the hydroxyethyl group was oxidized to the aldehyde, which was coupled with isobutyl (diethoxyphosphinyl)methanesulfonate through the Horner-Wadsworth-Emmons reaction to yield the sulfonate intermediate. The intermediate was further converted to the desired TMSP. Using the phosphoramidite units derived from nucleosides, we synthesized oligonucleotides incorporating TMSP. Oligonucleotides modified with TMSP were found to have duplex stability, resistance toward 3'-exonuclease digestion, and antisense activity comparable to that of the oligonucleotide modified with a previously reported 2'-O-methylcarbamoylethyl group. Based on these results and the generality of the synthetic scheme, 2'-O-sulfamoylalkyl modification is expected to be used for the modulation of the properties of oligonucleotides by changing the substituents on the nitrogen, enabling the oligonucleotides to possess suitable properties for antisense oligonucleotides.

Synthesis of 2'-O-alkylcarbamoylethyl-modified oligonucleotides with enhanced nuclease resistance that form isostable duplexes with complementary RNA.

To expand the variety of 2'-O-modified oligonucleotides, we synthesized 2'-O-carbamoylethyl-modified oligonucleotides bearing ethyl, n-propyl, n-butyl, n-pentyl, and n-octyl groups on their nitrogen atoms. The corresponding nucleosides were synthesized using 2'-O-benzyloxycarbonylethylthymidine, which was easily converted into the carboxylic acid through hydrogeneration; subsequent condensation with the appropriate amine gave the desired nucleoside. We evaluated the effect of the 2'-O-alkylcarbamoylethyl modifications on duplex stability by analyzing melting temperature, which revealed the formation of isostable duplexes. In addition, we also revealed that these modifications, especially octylcarbamoylethyl, endowed these oligonucleotides with resistance toward a 3'-exonuclease. These results highlight the usefulness of the 2'-O-alkylcarbamoylethyl modification for various biological applications.

Synthesis of Deoxypseudouridine 5'-Triphosphate Bearing the Photoremovable Protecting Group at the N1 Position Capable of Enzymatic Incorporation to DNA.

Enzymatic incorporation of deoxynucleoside 5'-triphosphate bearing the photocleavable protecting group is a useful method for the preparation of photocaged oligodeoxynucleotides. Here, we describe the synthesis of new photocaged deoxynucleoside triphosphates N1-(2-nitrobenzyl)-deoxypseudouridine triphosphate (dNBΨTP) and N1-(6-nitropiperonyloxymethyl)-deoxypseudouridine triphosphate (dNPOMΨTP). We successfully synthesized dNBΨTP and dNPOMΨTP and applied them to enzymatic synthesis of photocaged oligonucleotides. In addition, we also synthesized phosphoramidites of N1-(2-nitrobenzyl)- and N1-(6-nitropiperonyloxymethyl)-deoxypseudouridine to enable chemical synthesis of photocaged oligonucleotides incorporating them. The photocleavable 2-nitrobenzyl and 6-nitropiperonyloxymethyl in oligonucleotides were cleaved by irradiation at 365 nm for 30 and 10 s, respectively. We also studied the enzymatic incorporation of dNBΨTP and dNPOMΨTP using the Klenow fragment exo-. As a result, it was clarified that dNPOMΨTP could be incorporated to oligonucleotide 193 times more efficiently than dNBΨTP, as judged by Vmax/Km. We also performed the incorporation of at least eight dNPOMΨ residues in a 35-mer oligodeoxynucleotide. It has also been revealed that the oligodeoxynucleotides incorporating photocaged deoxypseudouridine were useful for photocontrol of DNA triplex formation.

Synthesis of 2'-O-(N-methylcarbamoylethyl) 5-methyl-2-thiouridine and its application to splice-switching oligonucleotides.

The effect of 2'-O-(N-methylcarbamoyl)ethyl (MCE) modification on splice-switching oligonucleotides (SSO) was systematically evaluated. The incorporation of five MCE nucleotides at the 5'-termini of SSOs effectively improved the splice switching effect. In addition, the incorporation of 2'-O-(N-methylcarbamoylethyl)-5-methyl-2-thiouridine (s2TMCE), a duplex-stabilizing nucleotide with an MCE modification, into SSOs further improved splice switching. These SSOs may be useful for the treatment of genetic diseases associated with splicing errors.

Tolerance of N2-heteroaryl modifications on guanine bases in a DNA G-quadruplex.

To systematically determine the effect of N2-heteroaryl modification on the stability of G-quadruplex structures, six types of N2-heteroarylated deoxyguanosines were incorporated into oligonucleotides with intramolecular quadruplex-forming sequences obtained from the human telomere sequence. A UV melting experiment, electrophoretic mobility shift assay, and circular dichroism were performed to evaluate the influence of N2-heteroaryl modification. Among the N2-heteroaryl modifications used in this study, N2-(pyrimidin-2-yl) modification markedly destabilized the G-quadruplex structure. Interestingly, N2-heteroaryl modification in the middle guanine base of the fourth strand was well-tolerated and formed a G-quadruplex, suggesting that the fourth strand is the least important strand in sustaining the G-quadruplex structure.

DNA triplex-based fluorescence turn-on sensors for adenosine using a fluorescent molecular rotor 5-(3-methylbenzofuran-2-yl) deoxyuridine.

Fluorescence turn-on sensors for adenosine were developed using DNA triplexes modified with a fluorescent molecular rotor 5-(3-methylbenzofuran-2-yl)deoxyuridine (dUMBF) and abasic sites. Binding of adenosine to the abasic site next to the dUMBF changed the microenvironment and conformation (from the twisted to planar state) of dUMBF and enhanced the fluorescence. Adenosine could be selectively detected over other nucleosides and adenosine phosphates. The binding of adenosine was confirmed by UV-thermal melting experiments. Further, the conformational changes of dUMBF from the twisted to coplanar state upon binding of adenosine was supported by MD simulations.

Modification of oligonucleotides with weak basic residues via the 2'-O-carbamoylethyl linker for improving nuclease resistance without loss of duplex stability and antisense activity.

For the improvement of nuclease resistance, four kinds of new modifications through a carbamoylethyl linker were designed. Among them, the 2'-O-[2-N-{2-(benzimidazol-1-yl)ethyl}carbamoylethyl] modification showed 20-fold longer half-life when treated with a 3' to 5' exonuclease compared to the 2'-O-methoxyethyl (MOE) modification, which is used in approved drugs. In addition, this large modification did not disturb the binding affinity or RNase H-dependent antisense activity. From these findings, it could be concluded that an adequate linker, such as carbamoylethyl in this study, could extend the utility of 2'-O-modification without loss of the properties of nucleic acids. This strategy would be useful for the development of nucleic acid therapeutics.

Deoxynucleoside Triphosphate Containing Pyridazin-3-one Aglycon as a Thymidine Triphosphate Substitute for Primer Extension and Chain Elongation by Klenow Fragments.

Deoxynucleoside 5'-triphosphate was synthesized with 3-oxo-2 H-pyridazin-6-yl (PzO)-a uracil analogue lacking a 2-keto group-as the nucleobase. Theoretical analyses and hybridization experiments indicated that PzO recognizes adenine (A) for formation of a Watson-Crick base pair. Primer extension reactions using nucleoside 5'-triphosphate and the Klenow fragment revealed that the synthetic nucleoside 5'-triphosphate was incorporated into the 3' end of the primer through recognition of A in the template strand. Moreover, the 3'-nucleotide residue harboring PzO as the base was resistant to the 3'-exonuclease activity of Klenow fragment exo+. The primer bearing the PzO base at the 3' end could function in subsequent chain elongation. These properties of PzO were attributed to the presence of an endocyclic nitrogen atom at the position ortho to the glycosidic bond, which was presumed to form an H-bond with the amino acid residue of DNA polymerase for effective recognition of the 3' end of the primer for primer extension. These results provide a basis for designing new nucleobases by combining a nitrogen atom at the position ortho to the glycosidic bond and base-pairing sites for Watson-Crick hydrogen bonding.

A kinetically controlled, isothermal method for the detection of single nucleotide mismatches.

We describe an isothermal, enzyme-free method to detect single nucleotide differences between oligonucleotides of close homology. The approach exploits kinetic differences in toe-hold-mediated, nucleic acid strand-displacement reactions to detect single nucleotide polymorphisms (SNPs) with essentially "digital" precision. The theoretical underpinning, experimental analyses, predictability, and accuracy of this new method are reported. We demonstrate detection of biologically relevant SNPs and single nucleotide differences in the let-7 family of microRNAs. The method is adaptable to microarray formats, as demonstrated with on-chip detection of SNP variants involved in susceptibility to the therapeutic agents abacavir, Herceptin, and simvastatin.

Fluorescence enhancement of oligodeoxynucleotides modified with green fluorescent protein chromophore mimics upon triplex formation.

Green fluorescent protein (GFP)-based molecular-rotor chromophores were attached to the 5-positions of deoxyuridines, and subsequently, incorporated into the middle positions of oligodeoxynucleotides. These oligonucleotides were designed to form triplex DNA in order to encapsulate the GFP chromophores, mimicking GFP structures. Upon triplex formation, the embedded GFP chromophores exhibited fluorescence enhancement, suggesting the potential application of these fluorescent probes for the detection of nucleic acids.

Synthesis of oligonucleotides containing 2-N-heteroarylguanine residues and their effect on duplex/triplex stability.

To systematically understand the effect of 2-N-heteroarylguanine (GHA) modification on the stability of higher-order DNA structures, nucleoside derivatives and oligodeoxyribonucleotides containing guanine residues modified with four kinds of hereroaryl groups on the 2-amino group were synthesized. The stabilities of the DNA duplex and the parallel-oriented DNA triplex containing these GHAs were studied by measuring their melting temperatures (Tm). Tm experiments and DFT calculations of the modified guanine nucleobases suggested that the base pair formation energy and stability of the two conformations, i.e., the open- and closed-type conformations, are key to determining the stability of the DNA duplex. Finally, the DNA triplex was destabilized when modified guanine residues were introduced into triplex-forming oligonucleotides.

Synthesis of photocaged 6-O-(2-nitrobenzyl)guanosine and 4-O-(2-nitrobenzyl) uridine triphosphates for photocontrol of the RNA transcription reaction.

6-O-(2-Nitrobenzyl)guanosine and 4-O-(2-nitrobenzyl)uridine triphosphates (NBGTP, NBUTP) were synthesized, and their biochemical and photophysical properties were evaluated. We synthesized NBUTP using the canonical triphosphate synthesis method and NBGTP from 2',3'-O-TBDMS guanosine via a triphosphate synthesis method by utilizing mild acidic desilylation conditions. Deprotection of the nitrobenzyl group in NBGTP and NBUTP proceeded within 60s by UV irradiation at 365nm. Experiments using NBGTP or NBUTP in T7-RNA transcription reactions showed that NBGTP could be useful for the photocontrol of transcription by UV irradiation.

Synthesis and triplex-forming properties of oligonucleotides capable of recognizing corresponding DNA duplexes containing four base pairs.

A triplex-forming oligonucleotide (TFO) could be a useful molecular tool for gene therapy and specific gene modification. However, unmodified TFOs have two serious drawbacks: low binding affinities and high sequence-dependencies. In this paper, we propose a new strategy that uses a new set of modified nucleobases for four-base recognition of TFOs, and thereby overcome these two drawbacks. TFOs containing a 2'-deoxy-4N-(2-guanidoethyl)-5-methylcytidine (d(g)C) residue for a C-G base pair have higher binding and base recognition abilities than those containing 2'-OMe-4N-(2-guanidoethyl)-5-methylcytidine (2'-OMe (g)C), 2'-OMe-4N-(2-guanidoethyl)-5-methyl-2-thiocytidine (2'-OMe (g)Cs), d(g)C and 4S-(2-guanidoethyl)-4-thiothymidine ((gs)T). Further, we observed that N-acetyl-2,7-diamino-1,8-naphtyridine ((DA)Nac) has a higher binding and base recognition abilities for a T-A base pair compared with that of dG and the other DNA derivatives. On the basis of this knowledge, we successfully synthesized a fully modified TFO containing (DA)Nac, d(g)C, 2'-OMe-2-thiothymidine (2'-OMe (s)T) and 2'-OMe-8-thioxoadenosine (2'-OMe (s)A) with high binding and base recognition abilities. To the best of our knowledge, this is the first report in which a fully modified TFO accurately recognizes a complementary DNA duplex having a mixed sequence under neutral conditions.

Synthesis of 5-[3-(2-aminopyrimidin-4-yl)aminopropyn-1-yl]uracil derivative that recognizes Ade-Thy base pairs in double-stranded DNA.

5-[3-(2-Aminopyrimidin-4-yl)aminopropyn-1-yl]uracil (Ura(Pyr)) was designed as a new nucleobase to recognize Ade-Thy base pair in double-stranded DNA. We successfully synthesized the dexoynucleoside phosphoramidite having Ura(Pyr) and incorporated it into triplex forming oligonucleotides (TFOs). Melting temperature analysis revealed that introduction of Ura(Pyr) into TFOs could effectively stabilize their triplex structures without loss of base recognition capabilities.

Photo-controlled binding of MutS to photo-caged DNA duplexes incorporating 4-O-(2-nitrobenzyl) or 4-O-[2-(2-nitrophenyl)propyl]thymidine.

Mismatch binding protein MutS binding to bulge structure in DNA duplexes was controlled by UV irradiation. 4-O-(2-Nitrobenzyl)thymidine or 4-O-[2-(2-nitrophenyl)propyl]thymidine was incorporated into DNA duplexes a bulged position. The MutS did not bind to the caged DNA duplexes but bound after removing the 2-nitrobenzyl or 2-(2-nitrophenyl)propyl group by photo-irradiation. By using photo-caged DNA duplex, we revealed that binding of MutS to the uncaged DNA downstream of the T7 RNA promoter weakly inhibited transcription by T7 RNA polymerase.

Effective Strategy for Conformer-Selective Detection of Short-Lived Excited State Species: Application to the IR Spectroscopy of the N1H Keto Tautomer of Guanine.

The ultrafast deactivation processes in the excited state of biomolecules, such as the most stable tautomers of guanine, forbid any state-of-the-art gas phase spectroscopic studies on these species with nanosecond lasers. This drawback can be overcome by grafting a chromophore having a long-lived excited state to the molecule of interest, allowing thus a mass-selective detection by nanosecond R2PI and therefore double resonance IR/UV conformer-selective spectroscopic studies. The principle is presently demonstrated on the keto form of a modified 9-methylguanine, for which the IR/UV double resonance spectrum in the C═O stretch region, reported for the first time, provides evidence for extensive vibrational couplings within the guanine moiety. Such a successful strategy opens up a route to mass-selective IR/UV spectroscopic investigations on molecules exhibiting natural chromophores having ultrashort-lived excited states, such as DNA bases, their complexes as well as peptides containing short-lived aromatic residues.